USE OF ELEMENTS FOR WRITING, DRAWING, MARKING, AND/OR PAINTING DEVICES, OR COSMETIC DEVICES, OR INPUT DEVICES
The use of an element for a writing, drawing, marking, and/or painting device, or cosmetic device, or input device for touch-sensitive surfaces, wherein the at least one element is a 3D-printed element. The at least one element has at least one main body and at least one structure. The at least one main body consists of a first material component. The at least one structure is provided as a visually detectable structure and/or at least one structure formed as a haptic zone. The at least one visually detectable structure and/or at least one structure formed as a haptic zone is a raised structure which projects from the surface, or the at least one visually detectable structure and/or at least one structure formed as a haptic zone is a decorated zone of the surface.
The invention relates to the use of elements for writing, drawing, marking and/or painting devices or cosmetic devices or input devices for touch-sensitive surfaces, wherein the elements are produced by means of 3D printing.
Components for such devices are known in principle.
Here mention may be made of components such as shafts or caps for writing, drawing, marking and/or painting devices whose main body is produced by extrusion and which have a constant cross-sectional profile over the entire length. The cross-sectional profiles can differ substantially from one another or be differently configured in terms of their geometries.
It should be seen to be disadvantageous here that deviations in the geometry and surface design, perpendicular to the extrusion direction such as for example indentations and/or elevated structures are not possible in a continuous process with such a method of manufacture. At least one additional process or working step is required to create such structures. Furthermore, it should be seen as disadvantageous that an individualization/personalization or individual design of the look and surface is not possible here in a simple manner.
Furthermore, it is possible to produce components for writing devices in the injection molding process. Here it is possible to produce or image the elements with raised but also recessed structures. It should be seen as a disadvantage here that injection molds are very expensive, in particular when products are to be made from several material components (2-K). Furthermore, it should be seen as disadvantageous that as a result of expensive molds, no individualizability is given in cases of small numbers of items. For example, a haptic design tailored to a person is not possible.
Components such as for example shafts are known from DE 102010030539 A1, where these components have elevated structures, wherein these structures are formed in one piece with the component. Here the surface of the component is heated with a laser which has the result that the heated plastic emerges from the surface of the component accompanying a change in the volume size. A disadvantage is that the described method requires a high energy expenditure and in addition is difficult to control. Each individual structure which is to be produced must be individually controlled. Furthermore, the energy input due to the laser beam is too high in some cases, with the result that partial combustions can occur on the component. In this highly technical expensive method, there is certainly a possibility for individualization in a certain sense but all modifications to the components are based on the base material of the component.
Components are further known which are produced in the corrugation process. This is understood as the subsequent treatment of an extruded strand using a so-called corrugator. Such a process is known for example from DE 102010056239 A1 for plastic tubes. In the process a freshly extruded strand of plastic is drawn into a corrugator in which the strand then runs through shaping jaws of the corrugator and a corrugated structure is formed according to the configuration of the shaping jaws. The plastic strand is thereby pressed into the cavities of the shaping jaws. This can for example be achieved or assisted by vacuum. It should be seen as disadvantageous here that no individualizability of the produced components is thus achieved. This is a costly process for creating large numbers of identical parts.
It is the object of the invention to provide elements for writing, drawing, marking and/or painting devices or cosmetic devices or input device for touch-sensitive surfaces, wherein the elements do not have the said disadvantages and wherein the elements in particular should have a haptically advantageous and/or decoratively configured surface.
It is further the object of the invention that the elements can be individually configured.
This object is solved with the features of the main claim. Advantageous configurations are covered by the features of the subclaims.
The object is solved by the use of at least one element for writing, drawing, marking and/or painting devices or cosmetic devices or input devices for touch-sensitive surfaces. The at least one element is configured as a 3D-printed element, wherein the at least one element comprises at least one main body and at least one structure. The at least one main body consists of a first material component, in which the at least one structure is provided as a visually detectable structure and/or at least one structure formed as a haptic zone. The at least one visually detectable structure and/or at least one structure formed as a haptic zone is configured as an indentation or recess in the surface. The at least one visually detectable structure and/or at least one structure formed as a haptic zone can be configured as a raised structure which projects from the surface. The at least one visually detectable structure and/or at least one structure formed as a haptic zone can be configured as a coloured and/or functionally decorated region of the surface.
The raised structure and/or the decorated region is formed in one piece with the at least one main body which means that the main body and the structure consist of the first material component. Alternatively, the raised structure and/or the decorated region can be formed from an at least second material component.
Haptic zones produce a pleasant feeling during handling for the user and prevent for example fatigue effects during writing for a fairly long time.
It has proved to be advantageous if visually detectable and/or haptic zones are designed or individually designed without a separate or additional manufacturing process needing to be used in addition to the 3D printing process.
The following methods can be used in 3D printing. Scan LED technology (SLT), multijet modelling (MJM), selective laser sintering (SLS), polyjet technology (PJ), stereo-lithography (SLA), vacuum casting, selective laser melting (SLM) and fused deposition modelling (FDM).
It can also be deemed to be advantageous in 3D printing processes that in addition to the printing of complete elements from one material component, elements consisting of two or more material components can also be produced. A first material component differs from a second or further material component in colour and/or composition.
Individual designs of elements which have been produced by means of 3D printing include, for example, structures such as signatures or lettering, pictorial diagrams and/or geometries of all kinds regardless of whether these are configured as raised structures, indentations, recesses and/or decorations.
The at least one visually detectable structure and/or at least one structure configured as a haptic and/or anti-slip region is frequently connected to the at least one main body in one piece, which means that main body and structure consist of a first material component.
Alternatively, the at least one visually detectable structure and/or at least one structure configured as a haptic and/or anti-slip region can be configured as a second or further material component.
For example, the first and/or at least second material component can consist of PLA, ABS, Nylon, rubber-like materials, resins and PP.
The use of an element according to the invention is described in detail with reference to the following figures and preferred exemplary embodiments are shown are described.
Here it should be noted that in
The method for producing elements for the use according to the invention is described for example of scan LED technology (SLT). The following essential steps are listed here.
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- Step 1: converting a 3-D geometry into a so-called STL file (=surface tessalation language)
- Step 2: transferring the STL file to a printer
- Step 3: software of the printer positions the geometry to be printed in the installation space of the printer
- Step 4: fixing the support geometry
- Step 5: fixing the positioning/position of the product to be printed
- Step 6: specifying the resolution of the printer—depending on the geometry to be printed
- Step 7: initiating the printing process, for example with so-called Fotomed materials (UV curing) as printing media
- Step 8: remove printed object from installation space
- Step 9: manual removal of the support geometry
- Step 10: possible manual removal of excess material
In addition to the said method of the scan LED process, the 3D printing can also be accomplished by other generative fabrication processes. For example, mention may be made of multijet modelling, selective laser sintering, polyjet technology, stereo-lithography, vacuum casting, or fused deposition modelling (FDM).
Various materials can be used for the 3D printing. For example, mention may be made of PLA, ABS, Nylon, rubber-like materials, resins and PP. For example, biocompatible materials can be used. Depending on the type of printer or the different 3D printing processes, there are material recommendations by the manufacturer and/or supplier.
REFERENCE LIST1 Writing, drawing, marking and/or painting device or cosmetic device or input device for touch-sensitive surfaces
10 Element
101 Raised structure
102 Indentation
103 Decorated region
104 Recesses
105 Ring structure
11 Main body
111 Surface
112 Thread
Claims
1-7. (canceled)
8. An element for writing, drawing, marking and/or painting devices or cosmetic devices or input devices for touch-sensitive surfaces, wherein the element is a 3D-printed element that comprises:
- a main body; and
- at least one structure, wherein the main body consists of a first material component, wherein the at least one structure is provided as a visually detectable structure and/or as at least one structure formed as a haptic zone,
- wherein the at least one visually detectable structure and/or the at least one structure formed as a haptic zone is an indentation or recess in a surface of the main body, or
- wherein at least one visually detectable structure and/or the at least one structure formed as a haptic zone is a raised structure that projects from the surface of the main body, or
- wherein the at least one visually detectable structure and/or the least one structure formed as a haptic zone is a decorated region of the surface of the main body.
9. The element according to claim 8, wherein the raised structure and/or the decorated region is formed in one piece with the main body and the main body and the structure consist of the first material component.
10. The element according to claim 8, wherein the raised structure and/or the decorated region is formed from a second material component.
11. The element according to claim 10, wherein the second material component is configured differently in color and/or composition compared with the first material component of the main body.
12. The element according to claim 8, wherein the first material component is selected from the group consisting of: PLA, ABS, Nylon, rubber-like materials, resins and PP.
13. The element according to claim 10, wherein the second material component is selected from the group consisting of: PLA, ABS, Nylon, rubber-like materials, resins and PP.
14. A method for producing an element according to claim 1, comprising the steps of:
- Step 1: converting a 3-D geometry into an STL file;
- Step 2: transferring the STL file to a printer;
- Step 3: using software of the printer, positioning the geometry to be printed in an installation space of the printer;
- Step 4: fixing a support geometry;
- Step 5: fixing a position of the element to be printed;
- Step 6: specifying a resolution of the printer, depending on the geometry to be printed;
- Step 7: initiating printing;
- Step 8: removing the printed element from the installation space; and
- Step 9: manually removing the support geometry.
15. The element according to claim 14, wherein Step 7 includes printing with UV curing materials as printing media.
Type: Application
Filed: Sep 30, 2016
Publication Date: Sep 27, 2018
Inventor: Klaus FISCHBÄCK (Nürnberg)
Application Number: 15/765,008